Units of `Lambda_(m)` are is S `m^(3) mol^(-1)` , if k is expressed in `Sm^(-)` and the concentration in mol `m^(-3)`.

Calculating The Degree of ionization: The molar conductance of an infinitely dilute solution NH_(4)Cl is 150 S cm^(2) mol^(-1) and the limiting ionic conductacnes of Cl^(-) and OH^(-) ions are 76 and 198 S cm^(2) mol^(-1) respectively. If the molar conductivity of a 0.01 M solution of NH_(4)OH is 9.6 S cm^(2) mol^(-1) , what will be its degree of ionization Strategy: At any concentration C , if alpha is the degree of ionization then it can be approximented to the ratio of molar conductivity Lambda_(m)^(c) at the concentration C to limiting molar conducting, Lambda_(m)^(0) . We are given Lambda_(m)^(c) but we need to find Lambda_(m)^(0) .

Molar conductance of a solution is given by the expression ^^m = (kxx1000mLL^(-1))/(c) Here c is the concentration in mol L^(-1) and k is expressed in ohm^(-1) cm^(-1) . Units of molar conductance are

Calculating molar conductance: The resistance of 0.01 M solution of an electrolyte was found to be 210 ohm at 25^(@)C . Calculate them molar conductance of the colution at 25^(@)C , if the cell constant is 0.88 cm^(-1) Strategy: First conductivity in Sm^(-1) (SI units) and then divide it by molar concentration in mole m^(-3) (SI units) to get molar conductance in Sm^(2) mol^(-1) .

Which of the following statemetn is // are correct ? I . Van't Hoff factor for 10^(-3) M CH_(3)COOH is 39//35 (wedge^(@)._(m)=350 S cm^(2) mol^(-1) and k=4xx10^(-5) S cm^(-1)). II. If wedge^(@)._(m) of KCl, LiCl, and KNO_(3) are 150, 115, and 145 S cm^(2) mol^(-1), then that of LiNO_(3) will be 110 S cm^(2) mo^(-1). III. In general, with increase in concentration, the specific conductance increases and reaches a maximum and then decreases with further increase in concentration.

Calculating the value of dissociation constant of weak electrolyte: The conductivity of 0.001028 mo L^(-1) acetic acid is 4.95 xx 10^(-5) S cm^(-1) . Calculate its dssociation constatnt if Lambda_(m)^(0) for acetic acid is 390.5 S cm^(2) mol^(-1) . Strategy: We can determine the value of the dissociation constant for week electrolytes once we know the Lambda_(m)^(0) and Lambda_(m) at any given concentration C .